Arrhythmia overview

Question 1

normal monocyte conduction

phase 0

Answer 1

initial, rapid depolarization of myocyte tissues; increase in Na+ influx; rapid depolarization overshoots electrical potential, brief period of repolarization

Question 2

normal monocyte conduction

phase 1

Answer 2

transient active K+ efflux; Ca2+ influx

Question 3

normal monocyte conduction

phase 2

Answer 3

calcium influx balanced by K+ efflux; plateau

Question 4

normal monocyte conduction

phase 3

Answer 4

membrane permeable to K+ efflux; repolarization

Question 5

normal monocyte conduction

phase 4

Answer 5

gradual depolarization; constant Na+ leak to intracellular space balanced K+ efflux (true resting membrane potential)

Question 6

SA action potential

phase 0

Answer 6

depolarization is due to influx of fast Ca2+

Question 7

SA action potential

phase 3

Answer 7

efflux of K to repolarize the cell (Ca2+ influx is halted)

Question 8

SA action potential

phase 4

Answer 8

pacemaker current by leaking Na+, eventually leaks enough to cause cell activation

Question 9

electrical activity initiated at

Answer 9

sinoatrial (SA) node

Question 10

SA node

Answer 10

• highest rate of spontaneous impulse generation

- largely influenced by ANS

Question 11

t/f other cells outside SA node can spontaneously generate impulses

Answer 11

true but these are normally overridden by the SA node because rate of generation of impulse is lower in these cells

Question 12

P wave

Answer 12

depolarization of atria in response to SA node triggering

Question 13

T wave

Answer 13

ventricular repolarization

Question 14

PR interval

Answer 14

• atrial depolarization plus AV nodal delay of impulse

- normal is 120 to 200 msec (.12-.2 sec)

Question 15

longer PR interval

Answer 15

heart block

Question 16

QT interval

Answer 16

• depolarization plus repolarization of ventricle
• normal is 200-400 msec (0.2-0.4 sec)
• dependent on HR

Question 17

higher QT interval

Answer 17

greater risk of ventricular arrhythmias

Question 18

automatic tachycardia

Answer 18

• abnormal impulse generation

- tissues compete with SA node for cardiac rhythm dominance

Question 19

automatic tachycardia typically occurs

Answer 19

when there is blockage at the AV node (prevents conduction from atria to ventricles) or in some bundle branch

Question 20

do you see tachycardia or bradycardia in automatic tachycardia?

Answer 20

both

Question 21

causes of automatic tachycardia

Answer 21

• digitalis glycosides
• catecholamines
• electrolyte abnormalities (hypokalemia)
• myocardial stretch (cardiac dilation)

Question 22

hypokalemia and cardiac elevation lead to an increased

Answer 22

slop 4 so they recover faster than SA node cells

Question 23

re-entrant tachycardia

Answer 23

• abnormal pulse conduction
• conducting pathway is stimulated prematurely by a previously conduction action potential leading to rapid cyclical reactivation

Question 24

re-entrant tachycardia occurs when

Answer 24

the pathway branches and then rejoins at a later point. one branch conducts signal quickly, one branch has slow conduction (not fully repolarized)

Question 25

is there an acceleration or deceleration phase in re-entrant tachycardia?

Answer 25

no. initiation and termination of tachycardia usually abrupt

Question 26

examples of re-entrant tachycardia

Answer 26

atrial fibrillation, atrial flutter, av nodal or an reentrant tachycardia, recurrent VT

Question 27

Vaughn Williams classification

Answer 27

drugs are classified by where they work in the action potential

Question 28

class Ia

Answer 28

procainamide, disopyramide, quinidine

Question 29

class Ib

Answer 29

lidocaine, mexiletine

Question 30

class Ic

Answer 30

flecainide, propafenone

Question 31

class II

Answer 31

beta blockers

Question 32

class III

Answer 32

dofetilide, ibutilide, sotalol, dronedarone, amiodarone

Question 33

class IV

Answer 33

non dhp ccbs

Question 34

procainamide

Answer 34

procan

Question 35

procainamide used for

Answer 35

ventricular tachycardia, a fib

Question 36

procainamide SE

Answer 36

drug induced lupus; agranulocytosis; QT prolongation

Question 37

procainamide clinical pearls

Answer 37

• active metabolite = NAPA

- monitor closely for renal disease

Question 38

lidocaine

Answer 38

xylocaine

Question 39

lidocaine uses

Answer 39

ventricular fibrillation, ventricular tachycardia

Question 40

lidocaine SE

Answer 40

hypotension and seizure at high doses

Question 41

lidocaine clinical pearls

Answer 41

• iv only

- metabolized in the liver: reduce dose

Question 42

flecainide

Answer 42

tambacor

Question 43

flecainide uses

Answer 43

ventricular tachycardia, supraventricular tachycardia

Question 44

flecainide SE

Answer 44

new or worsened arrhythmias; heart block; QT prolongation

Question 45

flecainide interactions

Answer 45

2D6 substrate

Question 46

flecainide clinical pearls

Answer 46

• po only
• renal dose adjustment
• worsens HF

Question 47

beta blockers are useful for

Answer 47

• exercise related tachycardia or other tachycardias induced by high sympathetic tone

Question 48

beta blockers decrease

Answer 48

conduction velocity and shorten refractory period

Question 49

dofetilide

Answer 49

tikosyn

Question 50

dofetilide use

Answer 50

• conversion of a fib to sinus rhythm

- maintenance of sinus rhythm after conversion

Question 51

dofetilide SE

Answer 51

HA; QT prolongation; bradycardia

Question 52

dofetilide interactions

Answer 52

3A4 substrate - black box warning

Question 53

dofetilide clinical pearls

Answer 53

• renal dose adjustment

- pharmacy/MD must be registered to use

Question 54

sotalol

Answer 54

betapace

Question 55

sotalol uses

Answer 55

ventricular tachycardia, a fib, a flutter

Question 56

sotalol SE

Answer 56

QT prolongation; bradycardia; NVD; bronchospasms

Question 57

sotalol interactions

Answer 57

warning with low K and HF

Question 58

sotalol clinical pearls

Answer 58

renal dose adjustment

Question 59

dronedarone

Answer 59

multaq

Question 60

dronedarone uses

Answer 60

a fib, a flutter

Question 61

dronedarone SE

Answer 61

liver failure; QT prolongation; HF; heart block

Question 62

dronedarone interactions

Answer 62

3A4 substrate - black box warning; digoxin - decrease dose by 50%; warfarin - start at 2.5mg

Question 63

dronedarone clinical pearls

Answer 63

must stop all class I and III agents first; similar to amiodarone without iodine

Question 64

initial action of amiodarone

Answer 64

b-blockade

Question 65

predominant effect with chronic use of amiodarone

Answer 65

prolongation of repolarization

Question 66

amiodarone most commonly prescribed as

Answer 66

antiarrhythmic

Question 67

amiodarone used in

Answer 67

VT, VF, a fib, a flutter, PSVT

Question 68

amiodarone half life

Answer 68

extremely long; 15 to 100 days

Question 69

amiodarone inhibits

Answer 69

glycoprotein and most cyp-p450 enzymes

Question 70

SE with chronic use of amiodarone

Answer 70

pulmonary fibrosis, hypothyroidism, hyperthyroidism, optic neuritis/neuropathy; increased LFTs, tremors/ataxia/peripheral neuropathy; photosensitivity/ blue-gray skin discoloration

Question 71

monitoring for pulmonary fibrosis

Answer 71

chest radiograph
baseline, then every 12 months
pulmonary function tests

Question 72

monitoring for hypothyroidism and hyperthyroidism

Answer 72

thyroid functions test

baseline, then every 6 months

Question 73

monitoring optic neuritis/neuropathy

Answer 73

ophthalmologic exam

baseline, then every 12 months

Question 74

monitoring increased LFTs

Answer 74

LFTs

baseline, then every 6 months

Question 75

monitoring bradycardia/heart block

Answer 75

ECG

baseline, then every 3-6 months

Question 76

monitoring for tremors, ataxia, and peripheral neuropathy

Answer 76

history and physical examination

each office visit

Question 77

monitoring photosensitivity/blue-gray skin discoloration

Answer 77

history and physical examination

each office visit

Question 78

calcium channel blockade

Answer 78

• slows conduction velocity

- prolongs repolarization = longer refractory period

Question 79

calcium channel blockers used for

Answer 79

• effective for SA/AV node automatic or reentrant tachycardia
• may slow ventricular response in supraventricular arrhythmia

Question 80

adenosine

Answer 80

adenocard

Question 81

adenosine use

Answer 81

psvt

Question 82

adenosine SE

Answer 82

flushing; chest burning; bronchospasm

Question 83

adenosine interactions

Answer 83

none, half life < 10 seconds

Question 84

adenosine clinical pearls

Answer 84

• iv only

- asystole when given